CN213137424U - Efficient plastic granules granulator - Google Patents

Abstract

The utility model relates to a plastic processing technology field just discloses an efficient plastic granules granulator, the on-line screen storage device comprises a base, one side of base is provided with the pan feeding device, one side of pan feeding device is provided with conveyer, conveyer's the other end is provided with crowded material device, crowded material device's below is provided with the device that gathers materials, the top right side fixed mounting of base has the mounting panel, the top of pan feeding device fixed connection mounting panel, the pan feeding device includes fixed mounting in the pan feeding bucket of mounting panel top one side, the pan feeding mouth has been seted up to top one side of pan feeding bucket, the internally mounted of pan feeding bucket has the auger, the axle head transmission of auger is connected with the driving motor who is fixed in mounting panel top one side. This efficient plastic granules granulator through the structure that sets up conveyer and conveyer department for can locate remaining raw materials to the conveyer and clear up through tearing anti-sticking film, possess advantages such as convenient clearance.

Description

Efficient plastic granules granulator

Technical Field

The utility model relates to a plastic processing technology field specifically is an efficient plastic granules granulator.

Background

Plastic granulation is a process of plastic mechanical processing, the quality and the process of plastic products can be continuously improved only by groping and mastering skills according to the performance and practice of a machine in the plastic granulation process, and a plastic particle granulator is required when granulation is carried out.

Most current plastic granules granulator is comparatively troublesome in the aspect of the clearance of cooling device department, can lead to the remaining of raw materials, and then leads to the jam of device, and the screening of granulation is not high-efficient enough simultaneously, has certain limitation, therefore we propose an efficient plastic granules granulator for solve this problem.

SUMMERY OF THE UTILITY MODEL

Technical problem to be solved

Not enough to prior art, the utility model provides an efficient plastic granules granulator possesses advantages such as convenient clearance, has solved above-mentioned technical problem.

(II) technical scheme

In order to achieve the above object, the utility model provides a following technical scheme: an efficient plastic granules granulator includes the base, its characterized in that: one side of base is provided with the pan feeding device, one side of pan feeding device is provided with conveyer, the other end of conveyer is provided with crowded material device, the below of crowded material device is provided with the device that gathers materials that is fixed in the base top surface.

The feeding device is communicated with the conveying device, the extruding device and the collecting device.

Preferably, the mounting panel is fixedly mounted on the right side of the top end of the base, and the feeding device is fixedly connected with the top of the mounting panel.

Preferably, the feeding device comprises a feeding barrel fixedly arranged on one side of the top of the mounting plate.

A feeding opening is formed in one side of the top end of the feeding barrel.

And the packing auger is arranged inside the charging barrel.

And the shaft end of the packing auger is in transmission connection with a driving motor fixed on one side of the top of the mounting plate.

The arrangement of the packing auger is used for pushing the raw materials into a subsequent device under the action of the driving motor after the raw materials enter from the feeding port.

Preferably, the conveying device comprises a conveying barrel fixedly arranged at the discharge end of the feeding device.

And cooling pipes are arranged on the upper side and the lower side of the transportation barrel.

The inside of haulage bucket is provided with the inner tube, the inside wall of inner tube is provided with anti-sticking film.

The inner tube extends to the inside of pan feeding device and fixed mounting has the spacing ring.

The cooling tube is arranged for cooling the raw material pushed by the feeding device, so that subsequent processing is facilitated.

The raw materials that pan feeding device department propelling movement comes are inside getting into the crowded material device through the inner tube, and the anti-sticking film of inner tube department can tear from the inner tube to this makes things convenient for follow-up clearance to the inside residual raw materials of transmission device.

Preferably, the material extruding device comprises a material extruding box fixedly installed on one side of the conveying device, which is far away from the material feeding device.

And a pushing device is arranged at the top end of the extruding box.

And the bottom end of the material extruding box is fixedly provided with a material extruding plate.

And a material cutting device is fixedly arranged at the bottom end of the material extruding box.

Preferably, the pushing device comprises an air cylinder fixedly arranged at the top of the extruding box.

And the output end of the air cylinder is fixedly provided with a push plate positioned in the material extruding box.

The blanking device comprises a blanking motor fixedly arranged at the bottom of the outer wall of the extrusion box.

And the shaft end of the cutting motor is fixedly connected with a cutting blade which is positioned right below the material extruding plate.

The material cutting device is used for cutting the raw materials extruded from the material extruding plate, so that the granulation effect is achieved.

Preferably, the material collecting device comprises a material collecting box arranged right below the material extruding device.

The top end of the material collecting box is provided with a material receiving frame.

The material receiving frame is arranged under the material extruding plate, and the cross sectional area of the material receiving frame is larger than that of the material extruding plate, so that the raw materials falling from the material extruding plate can fall to the material receiving frame

The bottom both sides of case that gathers materials all rotate and are connected with flexible post, the other end and the base fixed connection of flexible post.

A cam is arranged between the telescopic columns, and the back of the cam is in transmission connection with a cam motor.

The material collecting box is internally and slidably connected with a material collecting hopper, and a sieve plate is arranged in the material collecting hopper.

The cam can drive the material collecting box to shake up and down and is matched with the sieve plate, so that the effect of sieving materials is achieved.

Compared with the prior art, the utility model provides an efficient plastic granules granulator possesses following beneficial effect:

1. this efficient plastic granules granulator through the structure that sets up conveyer and conveyer department for can locate remaining raw materials to the conveyer and clear up through tearing anti-sticking film, possess advantages such as convenient clearance.

2. This efficient plastic granules granulator through the structure that sets up the device and the device department that gathers materials for can filter the granule of making effectively, it is also very convenient to take out the granule simultaneously.

3. This efficient plastic granules granulator through the structure that sets up crowded material device and crowded material device department for can be reciprocal cut crowded material, thereby reach the effect of high-efficient granulation, possess advantages such as granulation effect is good.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a front sectional view of the structure of the present invention;

FIG. 3 is a schematic view of the structure of the receiving hopper of the present invention;

FIG. 4 is a schematic view of the cooling tube structure of the present invention;

FIG. 5 is a schematic view of the structure of the material extruding device of the present invention;

fig. 6 is the structure diagram of the material collecting device of the present invention.

Wherein: 100. a base; 200. a feeding device; 300. a transportation device; 400. a material extruding device; 500. a material collecting device; 110. mounting a plate; 210. a charging barrel; 220. a feeding port; 230. a packing auger; 240. a drive motor; 310. a transportation barrel; 320. a cooling tube; 330. an inner tube; 340. an anti-adhesion film; 350. a limiting ring; 410. a material extruding box; 420. a pushing device; 421. a cylinder; 422. pushing the plate; 430. extruding a material plate; 440. a material cutting device; 441. a material cutting motor; 442. a material cutting blade; 510. a material collecting box; 520. a material receiving frame; 530. a telescopic column; 540. a cam; 550. a cam motor; 560. a material receiving hopper; 570. and (4) a sieve plate.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-6, the device includes a base 100, a feeding device 200 is disposed on one side of the base 100, a transporting device 300 is disposed on one side of the feeding device 200, an extruding device 400 is disposed on the other end of the transporting device 300, and a collecting device 500 is disposed below the extruding device 400.

The feeding device 200 is communicated with the conveying device 300 and the extruding device 400 and the collecting device 500.

Specifically, a mounting plate 110 is fixedly mounted on the right side of the top end of the base 100, and a feeding device 200 is fixedly connected to the top end of the left side of the mounting plate 110.

Specifically, the feeding device 200 includes a feeding barrel 210 fixedly installed at the left end of the mounting plate 110.

A feeding port 220 is formed in the right side of the top end of the feeding barrel 210 and used for feeding granulation raw materials.

An auger 230 is installed inside the charging bucket 210 for continuously conveying the granulating raw material in the charging bucket 210.

The auger 230 penetrates through the side wall of the feeding device 200 and is connected with a driving motor 240 in a transmission way.

The auger 230 is arranged to push the raw material into a subsequent device under the driving of the driving motor 240 after the raw material enters the charging barrel 210 from the charging port 220.

Specifically, the transporting device 300 includes a transporting barrel 310 fixedly installed at the left side of the material feeding device 200.

The upper and lower both sides of transport bucket 310 all are provided with cooling tube 320, and cooling tube 320 is current cooling apparatus, and the purpose is used for carrying out certain cooling to the raw materials that transport bucket 310 department passed through to this makes things convenient for subsequent granulation.

The inside of transport barrel 310 is provided with inner tube 330, and the inside wall of inner tube 330 is provided with anti-sticking film 340, and anti-sticking film 340 is the bonding with the inner wall of inner tube 330, and the one side that inner tube 330 was kept away from to anti-sticking film 340 is antiseized, and this kind of antiseized material is unanimous with the antiseized material of pan simultaneously.

The inner tube 330 extends into the feeding device 200 and is fixedly mounted with a retaining ring 350.

The raw material pushed from the feeding device 200 enters the extruding device 400 through the inner tube 330, and the anti-sticking film 340 at the inner tube 330 can be torn off from the inner tube 330, so as to facilitate the subsequent cleaning of the residual raw material in the conveying device.

Specifically, the extruding device 400 includes an extruding box 410 fixedly installed at the left side of the transporting device 300. The top end of the extrusion box 410 is provided with a pushing device 420. Specifically, the pushing device 420 includes an air cylinder 421 fixedly installed on the top of the extruding box 410.

The output end of the cylinder 421 is fixedly provided with a push plate 422 positioned in the squeezing box 410. The outer side surface of the push plate 422 is connected with the inner wall of the material extruding box 410 in a matched, sealed, sliding and fitting manner.

The push plate 422 is pushed by the cylinder 421 to reciprocate up and down, so as to achieve the effect of pushing materials up and down in a reciprocating manner.

The bottom end of the material extruding box 410 is fixedly provided with a material extruding plate 430, and a plurality of material extruding holes are formed in the material extruding plate 430. The bottom of the material extruding box 410 is communicated, and the material extruding plate 430 is fixedly installed at the bottom end of the material extruding box 410, so that the extruded raw materials can be extruded through the material extruding plate 430, that is, the raw materials can form a strip through the material extruding holes under the extruding action of the pushing device 420.

The bottom end of the right side of the extruding box 410 is fixedly provided with a material cutting device 440, and the material cutting device 440 is used for cutting the material strips falling from the extruding plate 430.

Specifically, the material cutting device 440 includes a material cutting motor 441 fixedly installed at the bottom end of the right side of the material extruding device 400.

The shaft end of the material cutting motor 441 is fixedly connected with the material cutting blade 442, the connection between the material cutting blade 442 and the shaft end of the material cutting motor 441 is firm enough, and meanwhile, the material cutting blade 442 is in a rotating state at the position of the material cutting motor 441, so that the material cutting blade can be matched with the reciprocating material pushing of the pushing device 420 to perform reciprocating cutting, and the effect of periodic material manufacturing is achieved.

The material cutting device 440 is configured to cut the material extruded from the material extruding plate 430, so as to achieve the effect of granulation.

Specifically, the collecting device 500 includes a collecting box 510 disposed right below the extruding device 400.

The top end of the material collecting box 510 is provided with a material receiving frame 520.

The receiving frame 520 is disposed under the material extruding plate 430, and the cross-sectional area of the receiving frame 520 is larger than that of the material extruding plate 430, so that the raw material falling from the material extruding plate 430 can fall to the receiving frame 520.

The bottom both sides of case 510 that gather materials all rotate and are connected with flexible post 530, the other end and the base 100 fixed connection of flexible post 530, and flexible post 530 is simple socket joint structure, and the top of flexible post 530 rotates with the bottom surface of case 510 that gathers materials to be connected, realizes that the flexible of the flexible post 530 of both sides is not interfered.

Be provided with cam 540 between the flexible post 530, the back transmission of cam 540 is connected with cam motor 550, the quantity of cam 540 and cam motor 550 is two, and the orientation nonconformity of two cam 540, one up down, under the synchronous start's of cam motor 550 circumstances, cam 540 can drive the case 510 that gathers materials and reciprocate like this, mutually support with flexible post 530 simultaneously, realize gathering the alternate transformation of case 510 bottom surface both sides height, reach the reciprocal relative movement's in sieve 570 surfaces effect of granule material.

The left side sliding connection of collection workbin 510 has receiving hopper 560, and the relation of connection of receiving hopper 560 and collection workbin 510 is unanimous with the relation of connection of drawer, and receiving hopper 560 can be taken out from collection workbin 510 to this makes things convenient for subsequent material of getting, and the inside of receiving hopper 560 is provided with sieve 570, and it is communicating with receiving frame 520 and receiving hopper 560 to connect material frame 520, and the quantity of sieve 570 is a plurality of, and the sieve mesh size of different sieve 570 is also inconsistent simultaneously, and the size of sieve 570 sieve mesh is from big to small from last to down.

Cam 540 can drive the material collecting box 510 to shake up and down, and simultaneously mutually cooperates with sieve plate 570 and telescopic column 530, thereby achieving the effect of sieving materials.

When the material collecting device is used, raw materials are poured into the material inlet 220, the raw materials are conveyed to the conveying device 300 under the action of the packing auger 230, the raw materials are cooled through the cooling pipe 320 and conveyed to the material extruding device 400, the cylinder 421 can drive the push plate 422 to extrude the raw materials in a reciprocating mode, the raw materials fall through the material extruding plate 430 and fall into the material collecting device 500 through the cut materials of the material cutting device 440, the cam 540 can drive the material collecting device 500 to sieve the materials, and the material collecting hopper 560 can be pulled out after the sieving is finished to complete granulation.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. A high efficiency plastic pellet granulator including a base (100), characterized by: one side of base (100) is provided with pan feeding device (200), one side of pan feeding device (200) is provided with conveyer (300), the other end of conveyer (300) is provided with crowded material device (400), the below of crowded material device (400) is provided with the device (500) that gathers materials that is fixed in base (100) top surface.

2. A high efficiency plastic pellet granulator as claimed in claim 1, wherein: the top right side fixed mounting of base (100) has mounting panel (110), the top of pan feeding device (200) fixed connection mounting panel (110).

3. A high efficiency plastic pellet granulator as claimed in claim 1, wherein: the feeding device (200) comprises a feeding barrel (210) fixedly arranged on one side of the top of the mounting plate (110);

a feeding opening (220) is formed in one side of the top end of the feeding barrel (210);

a packing auger (230) is arranged in the charging barrel (210);

the shaft end of the packing auger (230) is connected with a driving motor (240) which is fixed on one side of the top of the mounting plate (110) in a transmission way.

4. A high efficiency plastic pellet granulator as claimed in claim 1, wherein: the conveying device (300) comprises a conveying barrel (310) fixedly arranged at the discharging end of the feeding device (200);

the upper side and the lower side of the transportation barrel (310) are provided with cooling pipes (320);

an inner pipe (330) is arranged inside the transportation barrel (310), and an anti-sticking film (340) is arranged on the inner side wall of the inner pipe (330);

the inner pipe (330) extends to the inside of the feeding device (200) and is fixedly provided with a limiting ring (350).

5. A high efficiency plastic pellet granulator as claimed in claim 1, wherein: the extruding device (400) comprises an extruding box (410) fixedly arranged on one side of the conveying device (300) far away from the feeding device (200);

the top end of the extrusion box (410) is provided with a pushing device (420);

the bottom end of the extrusion box (410) is fixedly provided with an extrusion plate (430);

and a material cutting device (440) is fixedly arranged at the bottom end of the extruding box (410).

6. A high efficiency plastic pellet granulator as claimed in claim 5, wherein: the pushing device (420) comprises an air cylinder (421) fixedly arranged at the top of the extruding box (410);

the output end of the air cylinder (421) is fixedly provided with a push plate (422) positioned in the material extruding box (410).

7. A high efficiency plastic pellet granulator as claimed in claim 5, wherein: the material cutting device (440) comprises a material cutting motor (441) fixedly arranged at the bottom of the outer wall of the extrusion box (410);

and a material cutting blade (442) positioned right below the material extruding plate (430) is fixedly connected to the shaft end of the material cutting motor (441).

8. A high efficiency plastic pellet granulator as claimed in claim 1, wherein: the material collecting device (500) comprises a material collecting box (510) arranged right below the material extruding device (400);

the top end of the material collecting box (510) is provided with a material receiving frame (520);

both sides of the bottom end of the material collecting box (510) are rotatably connected with telescopic columns (530), and the other ends of the telescopic columns (530) are fixedly connected with the base (100);

a cam (540) is arranged between the telescopic columns (530), and the back of the cam (540) is connected with a cam motor (550) in a transmission way;

the material collecting box (510) is internally and slidably connected with a material collecting hopper (560), and a sieve plate (570) is arranged in the material collecting hopper (560).

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